A microelectromechanical actuator, comprising: a substrate, having a surface; a conductive beam suspended parallel to the substrate, displaceable along an axis normal to the surface of the substrate; a center electrode on the substrate under the beam; a pair of side electrodes on the substrate configured, when charged, to exert an electrostatic force normal to the surface of the substrate on the beam that repulses the beam from the substrate, and exerts a balanced electrostatic force on the beam in a plane of the surface of the substrate, the center conductive electrode being configured to shield the beam from electrostatic forces induced by the side electrodes from beneath the beam, and the center electrode being configured to have a voltage different from a voltage on the beam, to thereby induce an attractive electrostatic force on the beam.

Discharge circuits, devices and methods. In some embodiments, a MEMS device can include a substrate and an electromechanical assembly implemented on the substrate. The MEMS device can further include a discharge circuit implemented relative to the electromechanical assembly. The discharge circuit can be configured to provide a preferred arcing path during a discharge condition affecting the electromechanical assembly. The MEMS device can be, for example, a switching device, a capacitance device, a gyroscope sensor device, an accelerometer device, a surface acoustic wave (SAW) device, or a bulk acoustic wave (BAW) device. The discharge circuit can include a spark gap assembly having one or more spark gap elements configured to facilitate the preferred arcing path.

An electronic device includes a capacitor and a passivation layer covering the capacitor. The capacitor includes a first electrode, a dielectric layer disposed over the first electrode and a second electrode disposed over the dielectric layer. An area of the first electrode is greater than an area of the dielectric layer, and the area of the dielectric layer is greater than an area of the second electrode so that a side of the capacitor has a multi-step structure.

A semiconductor device includes first and second exposed electrical contacts and a cavity having a microelectromechanical system (MEMS) structure therein. A conductive path extends from the first exposed electrical contact to the cavity and an over-voltage protection element electrically is coupled between the first and second exposed electrical contacts.

An electronic device includes a capacitor and a passivation layer covering the capacitor. The capacitor includes a first electrode, a dielectric layer disposed over the first electrode and a second electrode disposed over the dielectric layer. An area of the first electrode is greater than an area of the dielectric layer, and the area of the dielectric layer is greater than an area of the second electrode so that a side of the capacitor has a multi-step structure.

Electronic device including: a MEMS sensor device including a functional structure which transduces a chemical or physical quantity into a corresponding electrical quantity; a cap including a semiconductive substrate; and a bonding dielectric region, which mechanically couples the cap to the MEMS sensor device. The cap further includes a conductive region, which extends between the semiconductive substrate and the MEMS sensor device and includes: a first portion, which is arranged laterally with respect to the semiconductive substrate and is exposed, so as to be electrically coupleable to a terminal at a reference potential by a corresponding wire bonding; and a second portion, which contacts the semiconductive substrate.

A MEMS resonator is equipped with a substrate, a moving structure suspended above the substrate in a horizontal plane formed by first and second axes, having first and second arms, parallel to one another and extending along the second axis, coupled at their respective ends by first and second transverse joining elements, forming an internal window. A first electrode structure is positioned outside the window and capacitively coupled to the moving structure. A second electrode structure is positioned inside the window. One of the first and second electrode structures causes an oscillatory movement of the flexing arms in opposite directions along the first horizontal axis at a resonance frequency, and the other electrode structure has a function of detecting the oscillation. A suspension structure has a suspension arm in the window. An attachment arrangement is coupled to the suspension element centrally in the window, near the second electrode structure.

A robust microelectromechanical structure that is less prone to internal or external electrical disturbances. The structure includes a mobile element with a rotor suspended to a support, a first frame anchored to the support and circumscribing the mobile element, and a second frame anchored to the support and circumscribing the mobile element between the mobile element and the first frame, electrically isolated from the first frame. The rotor and the second frame are galvanically coupled to have a same electric potential.

A sensor device and a method for manufacturing the sensor device. The sensor device is equipped with an impact element that includes an inner part of dielectric bulk material and an outer part of diamond-like coating material. The inner part is made to be lower at the edges than in the middle, and the outer part is formed of a diamond-like coating layer that covers the inner part. The DLC coated impact element is mechanically more robust than the rectangular prior art structures. Furthermore, the tapered form of the impact element improves conductivity of the DLC coating such that discharge of static buildup in the impact element is effectively enabled.

A digital micromirror device comprises an array of micromirror pixels, the array comprising a first micromirror pixel and a second micromirror pixel. The first micromirror pixel comprises a hinge, where the hinge is configured to tilt toward a first raised address electrode and toward a second raised address electrode. The first micromirror pixel also comprises a first micromirror coupled to the hinge, where the first micromirror has a sculpted edge. The second micromirror pixel comprises a second micromirror, where a first gap between a first point on the sculpted edge and a nearest point to the first point on the second micromirror is larger than a second gap between a second point on the sculpted edge and a nearest point to the second point on the second micromirror.